Information display apparatus

ABSTRACT

A head-up display apparatus includes a display panel configured to display an image, and a reflecting mirror configured to reflect light from the display panel. An optical distance between the reflecting mirror and the display panel is changed to continuously change a display position of a virtual image from a distant place to an adjacent position such that a virtual image obtained by being reflected at an upper portion of a windshield is formed farther than a virtual image obtained by being reflected at a lower portion of the windshield when viewed from a viewpoint position of a driver.

CROSS-REFERENCE

This application is a continuation under 35 U.S.C. § 111(a) of U.S.patent application Ser. No. 17/538,520, filed on Nov. 30, 2021, which inturn is a continuation under 35 U.S.C. § 111(a) of U.S. patentapplication Ser. No. 16/094,173, filed on Oct. 16, 2018, now U.S. Pat.No. 11,221,480 issued on Jan. 11, 2022, which in turn is the U.S.National Phase under 35 U.S.C. § 371 of International Patent ApplicationNo. PCT/JP2016/063068, filed on Apr. 26, 2016, the entire disclosures ofwhich Applications are incorporated by reference herein.

TECHNICAL FIELD

The present invention relates to an information display apparatus thatprojects that projects an image on a windshield of a vehicle, anelectric train, an airplane or the like (hereinafter, generally referredto as “conveyance”). The present invention also relates to a projectionoptical system in which an image is observed through the windshield as avirtual image and an information display apparatus using the same.

BACKGROUND ART

A so-called head-up display (HUD: Head-Up-Display) apparatus has alreadybeen known by Patent Document 1 below. The head-up display apparatusproject video light onto a windshield of a vehicle to form a virtualimage, thereby displaying traffic information such as route informationor traffic jam information and vehicle information such as a remainingamount of fuel or cooling water temperature thereon.

It is desirable that this type of information display apparatus is to beminiaturized because a main body of the HUD apparatus is arrangedbetween a steering and a window glass in front of a driver's seat.

On the other hand, for example, an apparatus whose body is attached tothe vicinity of a ceiling (or a sun visor) of a vehicle as alsodisclosed in Non-Patent Document 1 below has been proposed.

RELATED ART DOCUMENTS Patent Documents

Patent document 1: Japanese Unexamined Patent Application PublicationNo. 2015-194707

Non-Patent Documents

Non-Patent document 1: PIONEER R&D (Vol. 22, 2013)

SUMMARY OF THE INVENTION Problems to be Solved by the Invention

As shown in FIG. 27 , a principle of generation of a virtual image by aconcave mirror to realize a head-up display apparatus according to aconventional technique arranges an object point AB at an inner side of afocal point F (focal point distance f) with respect to a point O on anoptical axis of a concave mirror 1′, thereby allowing the virtual imageby the concave mirror 1′ to be obtained. In FIG. 27 , for convenience ofexplanation, the concave mirror 1′ is regarded as a convex lens with thesame positive refractive power, and a relationship among an objectpoint, the convex lens (described by the concave mirror in FIG. 27 forconvenience of explanation), and the virtual image to be generated isshown.

In the conventional technique, the object point AB should be caused toapproach the focal point F in order to enlarge a size of the virtualimage to be generated on the concave mirror 1′. However, in order toobtain desired magnification, a radius of curvature of the concavemirror becomes smaller. As a result, a mirror size becomes smaller, andthis results in a state where only a virtual image whose effectivelyviewable range, in which magnification power is large, is small can beobtained. For this reason, in order to satisfy (1) a desired size of avirtual image, and (2) necessary magnification of the virtual imageM=b/a at the same time, it is necessary that a dimension of the concavemirror is fitted to a viewing range and magnification of the virtualimage is determined in view of a video display apparatus.

For this reason, in the conventional technique, in order to obtain avirtual image with a desired size, as shown in FIG. 27 , it is necessarythat a distance from the concave mirror 1′ to the virtual image becomeslarger, and as a result, a dimension of the information displayapparatus must become larger.

Moreover, as described above, with respect to a size of a virtual imageviewed and recognized by a driver, a distance “a” between the videodisplay apparatus and the concave mirror 1′ and a distance “b” betweenthe concave mirror 1′ and the virtual image are different between anupper end and a lower end of the virtual image, which is caused byinclination of a windshield. Therefore, it was difficult that imagemagnification in an upper end portion of the virtual image is caused tosubstantially correspond with image magnification in a lower end portionof the virtual image. For this reason, it is necessary that a differencebetween an upper optical path and a lower optical path is maderelatively smaller by causing the dimension “b” mentioned above tobecome larger, thereby reducing a partial change in image magnification(distortion of an image). Examination to reduce volume of theinformation display apparatus has been carried out by providing anoptical path folding mirror between the video display apparatus and theconcave mirror 1′.

Further, in the example of the head-up display apparatus disclosed inPatent Document 1 described above, the head-up display apparatusincludes a device configured to display an image and a projectionoptical system configured to project the image displayed by the displaydevice. The projection optical system includes a first mirror and asecond mirror on an optical path of a viewer from the display device.Miniaturization is realized by satisfying predetermined conditions for arelationship among an incident angle of the first mirror in a long axisdirection of the image, an incident angle of the first mirror in a shortaxis direction of the image, an interval between an image displaysurface of the display device and the first mirror, and a width of avirtual image viewed and recognized by the viewer in a horizontaldirection.

However, although it will be described later, as a result of theexamination by the inventors, it was found that in order to make volumeof a set the smallest, this can be realized without changing a size ofthe virtual image and providing a folding mirror (121 in FIG. 2 ofPatent Document 1) by shortening a focal point distance of a concavemirror (122 in FIG. 2 of Patent Document 1), which creates the virtualimage and shortening a distance between a position of the display deviceand the focal point of the concave mirror.

On the other hand, in the apparatus whose body is attached to thevicinity of the ceiling (or the sun visor) of the vehicle as disclosedin Non-Patent Document 1, in a case where the vehicle causes a collisionaccident and the HUD apparatus is thereby disengaged, safety problemsremain such as a possibility that a driver may be injured. Therefore,the inventors thought that the method described in Patent Document 1described above would become mainstream in the future.

Moreover, in Patent Document 1 described above, in a case where aplurality of viewpoint positions of the driver exists on a reflectingsurface of a windshield that is a projected member (220), the projectionoptical system is optimized as shown in all embodiments on the groundthat a central position of a radius of curvature in a vertical directionof a vehicle body of the windshield is different from that of a radiusof curvature in a horizontal direction of the vehicle body and thewindshield has a toroidal shape.

Further, in first, second, third, fourth, sixth, and seventh embodimentsof Patent Document 1 mentioned above, by arranging two mirrors betweenthe driver and the display device within substantially the same plane,miniaturization of a set size is realized. In addition, in order to makea size of the second mirror having a reflecting surface with a concavesurface shape, which generates the virtual image, smaller, distortion ofthe virtual image in the whole view point area is reduced up to a levelpractically having no problem by setting each reflecting surface of thefirst mirror having a reflecting surface with a convex shape to afree-form surface.

Further, in a fifth embodiment thereof, by causing the first mirror tohave a toroidal surface with the convex shape as the reflecting surface,the mirror is manufactured easily. On the other hand, the second mirroris caused to be the concave mirror with a free-form surface shape aswell as the other embodiments.

In the invention disclosed in Patent Document 1 described above, it isnecessary to arrange the two mirrors between an observer and the displaydevice. In addition, in order to arrange them so that reflected lightflux by the first mirror is not blocked out by the second mirror, thedegree of freedom of arrangement is lost and close arrangement cannot bemade. Therefore, it may cause a problem for miniaturization of the set.On the other hand, with respect to correction of aberration that occursin the virtual image viewed by the driver, necessity of the correctionand a concrete method of reducing the same has never been described andconsidered in Patent Document 1.

It is an object of the present invention to provide an informationdisplay apparatus capable of forming a virtual image with highvisibility, in which distortion and aberration of the virtual imageviewed and recognized by a driver are reduced up to a level practicallyhaving no problem, while suppressing increase in size and complicationof a set by configuring one mirror as a mirror having a reflectingsurface of a concave surface on which the virtual image is formed andarranging a lens whose cross section of at least one surface is aconcave surface (having negative refractive power) between the driverand a display device in order to miniaturize the apparatus.

Means for Solving the Problem

One example of the present disclosure that is made in order to achievethe object described above is a head-up display apparatus including adisplay panel configured to display an image, and a reflecting mirrorconfigured to reflect light from the display panel. An optical distancebetween the reflecting mirror and the display panel is changed tocontinuously change a display position of a virtual image from a distantplace to an adjacent position such that a virtual image obtained bybeing reflected at an upper portion of a windshield is formed fartherthan a virtual image obtained by being reflected at a lower portion ofthe windshield when viewed from a viewpoint position of a driver.

Effects of the Invention

According to the present disclosure, it becomes possible to provide aninformation display apparatus capable of forming a virtual image withhigh visibility by correcting distortion and/or aberration of thevirtual image observed by a driver while realizing miniaturization ofthe apparatus.

BRIEF DESCRIPTIONS OF THE DRAWINGS

FIG. 1 is a schematic configuration diagram showing a schematicconfiguration of an information display apparatus and peripheralequipment that is assigned to the information display apparatus;

FIG. 2 is a top view of a vehicle on which the information displayapparatus according to the present invention is mounted;

FIG. 3 is a configuration diagram for explaining a difference of aradius of curvature of a windshield;

FIG. 4 is a schematic configuration diagram showing the informationdisplay apparatus, the windshield, and a viewpoint position of a driver;

FIG. 5 is a schematic configuration diagram showing one embodiment of avirtual image optical system in the information display apparatusaccording to the present invention;

FIG. 6 is a schematic configuration diagram showing arrangement of thevirtual image optical system in the information display apparatus as anembodiment of the present invention;

FIG. 7 is a diagram showing a relationship between a distance between aconcave mirror and a video display apparatus of the virtual imageoptical system in the information display apparatus according to thepresent invention and a dimension of the apparatuses;

FIG. 8 is a diagram showing a relationship between the distance betweenthe concave mirror and the video display apparatus of the virtual imageoptical system in the information display apparatus according to thepresent invention and volume of the apparatuses;

FIG. 9 is a schematic view for explaining a principle of the presentinvention;

FIG. 10 is a configuration diagram showing arrangement of the videodisplay apparatus and a light source apparatus in the informationdisplay apparatus according to the present invention;

FIG. 11 is a schematic configuration diagram showing a configuration ofthe light source apparatus in a video display unit according to thepresent invention;

FIG. 12 is a schematic configuration diagram showing a shape of a lightguide element in the light source apparatus according to the presentinvention;

FIG. 13 is a schematic configuration diagram showing a cross-sectionalshape of the light guide element in the light source apparatus accordingto the present invention;

FIG. 14 is a schematic view for explaining an emission status of a lightflux from the video display apparatus and the light source apparatus inthe information display apparatus according to the present invention;

FIG. 15 is a characteristic diagram for explaining emission lightdistribution of the light flux from the light source apparatus for thevideo display apparatus in the information display apparatus accordingto the present invention;

FIG. 16 is a conceptual diagram showing a method of characteristicevaluation for a liquid crystal panel as the video display apparatus;

FIG. 17 is a characteristic diagram showing a transmittancecharacteristic of a screen in a horizontal direction of the liquidcrystal panel as the video display apparatus;

FIG. 18 is a characteristic diagram showing an angular characteristic ofbrightness of the screen in the horizontal direction in a case wherewhite is displayed on the liquid crystal panel as the video displayapparatus;

FIG. 19 is a characteristic diagram showing an angular characteristic ofbacklight brightness in the horizontal direction of the liquid crystalpanel as the video display apparatus;

FIG. 20 is a characteristic diagram showing the angular characteristicof transmittance in a vertical direction of the liquid crystal panel asthe video display apparatus;

FIG. 21 is a characteristic diagram showing the angular characteristicof brightness in the vertical direction when white is displayed on theliquid crystal panel as the video display apparatus;

FIG. 22 is a characteristic diagram showing an angular characteristic ofbacklight brightness in the vertical direction of the liquid crystalpanel as the video display apparatus;

FIG. 23 is a characteristic diagram showing an angular characteristic ofcontrast in the horizontal direction of the liquid crystal panel as thevideo display apparatus;

FIG. 24 is a characteristic diagram showing an angular characteristic ofblack display brightness in the horizontal direction of the liquidcrystal panel as the video display apparatus;

FIG. 25 is a characteristic diagram showing an angular characteristic ofcontrast in the vertical direction of the liquid crystal panel as thevideo display apparatus;

FIG. 26 is a characteristic diagram showing an angular characteristic ofblack display brightness in the vertical direction of the liquid crystalpanel as the video display apparatus; and

FIG. 27 is a schematic view for explaining a principle of a virtualimage optical system according to a conventional technique.

DETAILED DESCRIPTION OF EMBODIMENTS

Hereinafter, various kinds of embodiments of the present invention willbe described in detail with reference to the drawings and the like. Notethat the following explanation illustrates specific examples of thecontent of the present invention; the present invention is not limitedto this explanation; and various changes and modifications can be madeby a person having ordinary skill in the art within a scope of technicalideas disclosed in the present specification. Further, in all of thedrawings for explaining the present invention, the same referencenumeral may be attached to a component having the same function, andrepeated explanation may be omitted.

Embodiments of Information Display Apparatus

FIG. 1 is a block diagram and a schematic configuration diagram showinga peripheral equipment configuration of an information display apparatusaccording to one embodiment of the present invention. Here, aninformation display apparatus configured to project an image onto awindshield of a vehicle will be described particularly as one examplethereof.

An information display apparatus 100 is an apparatus (that is, aso-called HUD (Headup Display)) configured to display, as a virtualimage VI (Virtual Image), various kinds of information that arereflected by a projected member 6 (in the present embodiment, an innersurface of the windshield) in order to form a virtual image V1 at afront side of an own vehicle along a line of sight 8 of a driver. Inthis regard, the projected member 6 may be a member on which informationis projected, and it may be not only the windshield described above, butalso a combiner. Namely, in the information display apparatus 100according to the present embodiment, the projected member 6 may be amember that allows the driver to view (and recognize) a virtual imagethat is formed at the front side of the own vehicle along the line ofsight 8 the driver. As a matter of course, vehicle information, andinformation on the foreground photographed by cameras (not shown in thedrawings), such as a monitoring camera or an around viewer, arecontained as the information to be displayed as the virtual image, forexample.

Further, the information display apparatus 100 includes a video displayapparatus 4, a concave mirror 1, and a group of lenses 2 for correctionprovided between the video display apparatus 4 and the concave mirror 1.The video display apparatus 4 is configured to project video light todisplay information. The group of lenses 2 is configured to correctdistortion and/or aberration that occurs when a virtual image is formedby a concave mirror 1 from video displayed by the video displayapparatus 4.

The information display apparatus 100 also includes a controller 40configured to control the video display apparatus 4 described above anda backlight 5. Note that optical components including the video displayapparatus 4 and the backlight 5 described above is a virtual imageoptical system, which will be described later, and includes the mirror 1with a concave surface shape, which reflects light. Further, the lightreflected by these optical components is reflected by the projectedmember 6 to go toward the line of sight 8 of the driver (EyeBox: whichwill be described later).

As the video display apparatus 4 described above, for example, there area light emitting VFD (Vacuum Fluorescent Display) and the like inaddition to an LCD (Liquid Crystal Display) having a backlight.

On the other hand, in place of the video display apparatus 4 describedabove, video may be displayed on a screen by a projection apparatus, avirtual image may be formed therefrom by the concave mirror 1 describedabove and reflected by a windshield 6 that is the projected member todirect to the line of sight 8 of the driver.

As such a screen, for example, the screen may be configured by amicrolens array in which microlenses are arranged thereon in atwo-dimensional manner.

More specifically, in order to reduce distortion of the virtual image, ashape of the concave mirror 1 may have a shape in which a radius ofcurvature at an upper portion shown in FIG. 1 (that is, an area where aray is reflected at a lower part of the windshield 6 at which a distancefrom a viewpoint of the driver is relatively short) so thatmagnification power thereof becomes larger is relatively small, and aradius of curvature at a lower portion thereof (that is, an area where aray is reflected at an upper part of the windshield 6 at which adistance from the viewpoint of the driver is relatively long) so thatmagnification power thereof becomes smaller is relatively large.Further, a difference of virtual image magnifications described above iscorrected by inclining the video display apparatus 4 with respect to anoptical axis of the concave mirror to reduce distortion itself that mayoccur, whereby good correction can further be realized.

On the other hand, as shown in FIG. 2 , with respect to the windshield 6of the vehicle, a radius of curvature Rv in a vertical direction of abody thereof is different from a radius of curvature Rh in a horizontaldirection, and they generally have a relationship of Rh>Rv. For thisreason, as shown in FIG. 3 , when the windshield 6 is grasped as areflecting surface, it becomes a toroidal surface of the concave mirror.For this reason, in the information display apparatus according to thepresent invention shown in FIG. 3 , the shape of the concave mirror 1may have different average radii of curvature between the horizontaldirection and the vertical direction so as to correct the virtual imagemagnification by a shape of the windshield 6, that is, so as to correcta difference between the radii of curvature in the vertical directionand the horizontal direction of the windshield. In this case, in a casewhere the shape of the concave mirror 1 is a spherical or asphericalshape symmetric about the optical axis (that is, a shape expressed byFormula 2, which will be described later), it becomes a function of adistance r from the optical axis, a horizontal cross-sectional shape anda vertical cross-sectional shape of separated places cannot becontrolled individually. Therefore, it is preferable to correct thedifference as a function of a coordinate (x, y) on a surface from theoptical axis of a mirror surface as a free-form surface expressed byFormula 1 (will be described later).

The explanation returns to FIG. 1 again. A lens element 2 is furtherarranged between the video display apparatus 4 and the concave mirror 1as a transmissive optical component, for example. By controlling anemission direction of the ray to the concave mirror, aberrationcorrection of the virtual image including astigmatism that occurs due tothe difference between the radius of curvature in the horizontaldirection and the radius of curvature in the vertical direction of thewindshield 6 described above is realized at the same time as correctionof distortion aberration is carried out in accordance with the shape ofthe concave mirror.

Further, in order to further heighten aberration correction capability,an optical element 2 as described above may be constituted by aplurality of lenses. Alternatively, by arranging a curved mirror inplace of the lens element and controlling an incident position of theray to the concave mirror 1 at the same time of folding of the opticalpath, it is possible to reduce distortion aberration. As describedabove, it goes without saying that it does not depart from technicalideas or a range of the present invention even though an optical elementoptimally designed to improve the aberration correction capability isfurther provided between the concave mirror 1 and the video displayapparatus 4. Moreover, by changing a thickness of the optical element 2described above in an optical axis direction, an optical distancebetween the concave mirror 1 and the video display apparatus 4 can bechanged in addition to true aberration correction, whereby it ispossible to continuously change a display position of the virtual imagefrom a distant place to an adjacent position.

Further, by arranging the video display apparatus 4 so as to incline thesame with respect to a normal line of the optical axis of the concavemirror 1, the difference of magnifications of the virtual image in thevertical direction may be corrected.

On the other hand, as a factor to deteriorate image quality of theinformation display apparatus, there is known a fact that a video lightray emitted from the video display apparatus 4 toward the concave mirror1 is reflected by a surface of the optical element 2 arranged in themiddle to return to the video display apparatus, and is then reflectedagain to be superimposed on true video light, whereby the image qualitythereof is deteriorated. For this reason, in the present invention, itis preferable that the information display apparatus is designed so thatnot only antireflection coating is formed on the surface of the opticalelement 2 to suppress the reflection, but also a lens surface shape ofany one or both of an incident surface and an emission surface of theoptical element 2 for the video light is caused to have restriction of ashape so that the reflected light described above does not extremelyfocus on a part of the video display apparatus 4.

Next, in a case where a liquid crystal panel in which a polarizing plateis arranged in order to absorb the reflected light from the opticalelement 2 described above is used as the video display apparatus 4, itis possible to reduce deterioration in image quality. Further, thebacklight 5 of the liquid crystal panel is controlled so that anincident direction of light incident on a liquid crystal panel 4efficiently enters an incident eye of the concave mirror 1. Moreover, asthe light source, a solid light source with long product lifetime may beadopted. Furthermore, it is preferable that polarization conversion iscarried out by using a PBS (Polarizing Beam Splitter) in which opticalmeans for reducing a divergent angle of light as LED (Light EmittingDiode) whose change in light output with respect to variation in ambienttemperature is small is provided.

Polarizing plates are respectively arranged at the backlight 5 side(light incident surface) and the optical element 2 side (light emissionsurface) of the liquid crystal panel, thereby heightening a contrastratio of the video light. In a case where iodine-based one in which thedegree of polarization is high is adopted for the polarizing plateprovided at the backlight 5 side (light incident surface), a highcontrast ratio can be obtained. On the other hand, by using a dye-basedpolarizing plate for one provided at the optical element 2 side (lightemission surface), it becomes possible to obtain high reliability evenin a case where outside light enters or ambient temperature is high.

In a case where the liquid crystal panel is used as the video displayapparatus, in particular, in a case where the driver wears polarizedsunglasses in such a situation, a specific polarized wave is blocked orshielded, whereby a defect in which video cannot be viewed occurs. Inorder to prevent this situation, it is preferable that a λ/4 plate isarranged at a side of the optical element of the polarizing plate thatis arranged at the optical element 2 side of the liquid crystal panel,whereby the video light uniformed to a specific polarization directionis converted into circular polarized light.

The controller 40 obtains, from such a navigation system 61, variouskinds of information such as a speed limit and the number of lanes of aroad corresponding to a current position at which the own vehicle istravelling, and a scheduled movement route of the own vehicle set to thenavigation system 61 as foreground information (that is, information tobe displayed at a front of the own vehicle by the virtual imagedescribed above).

A driving support ECU 62 is a controller that realizes driving supportcontrol by controlling a drive system and a control system in accordancewith an obstacle detected as a result of monitoring by a circumferencemonitoring device 63. The driving support control includes well-knowntechnologies such as cruise control, adaptive cruise control, pre-crushsafety, lane keeping assist, for example.

The circumference monitoring device 63 is a device for monitoring astatus of a circumference of the own vehicle. As one example, there area camera that detects an object existing on the circumference of the ownvehicle on the basis of an image obtained by photographing thecircumference of the own vehicle, an exploratory device that detects anobject existing around the own vehicle on the basis of a result obtainedby transmitting and receiving an exploratory wave, and the like.

The controller 40 obtains such information from the driving support ECU62 (for example, a distance to a preceding vehicle and a direction ofthe preceding vehicle, a position at which an obstacle or a traffic signexists, and the like) as foreground information. Moreover, an ignition(IG) signal and own vehicle state information are inputted to thecontroller 40. The own vehicle state information among these kinds ofinformation is information obtained as the vehicle information. Forexample, the own vehicle state information contains warning informationindicating to become an abnormal state defined in advance, such asresidual quantity of fuel for an internal-combustion engine ortemperature of cooling water. Further, the own vehicle state informationalso contains an operational result of a direction indicator, travellingspeed of the own vehicle, and shift position information. The controller40 that has been mentioned above is activated when the ignition signalis inputted thereto. As the above, the whole system of the informationdisplay apparatus according to the present invention has been described.

First Embodiment of Virtual Image Optical System

Next, further details of a virtual image optical system according to thepresent invention and the video display apparatus will be describedbelow.

As have already been mentioned above, FIG. 2 is a top view of thevehicle on which the information display apparatus according to thepresent invention is mounted. A windshield exists as the projectedmember 6 in front of a driver's seat of a vehicle body 101. Note that aninclination angle of this windshield with respect to the vehicle body isdifferent depending upon a type of the vehicle. Moreover, the inventorsresearched this radius of curvature in order to realize an optimumvirtual image optical system. As a result, as shown in FIG. 3 , theinventors found that in the windshield, the radius of curvature Rh inthe horizontal direction parallel to a contact surface of the vehicle isdifferent from the radius of curvature Rv in the vertical directionorthogonal with respect to a horizontal axis, and there is generally arelationship below between Rh and Rv.

Rh>Rv

Further, it was also found that most of vehicles has this differencebetween the radii of curvature, that is, the Rh with respect to Rv in arange from 1.5 times to 2.5 times.

Next, the inventors also researched commercial products with respect tothe inclination angle of the windshield. As a result, although it isdifferent depending upon a vehicle body type, it was 20° to 30° in alight motor vehicle or a minivan type, 30° to 40° in a sedan type, and40° or more in a sports type. Thus, in the present invention, adifference between the radius of curvature Rh in the horizontaldirection of the windshield parallel to the contact surface of thevehicle and the radius of curvature Rv in the vertical directionorthogonal to the horizontal axis and the inclination angle of thewindshield were considered to design the virtual image optical system.

More specifically, since the horizontal radius of curvature Rh and thevertical radius of curvature Rv of the windshield that is the projectedmember are greatly different from each other, good aberration correctionwas realized by providing the optical element 2 in the virtual imageoptical system. The optical element 2 is axially asymmetric with thehorizontal axis of the windshield with respect to the optical axis (Zaxis) and the axis vertical to this axis.

Next, the inventors carried out examination for miniaturization of theinformation display apparatus 100. As a condition of the examination,horizontal: 7° and vertical: 2.6° of FOV were set, and a virtual imagedistance is further set to 2 m, whereby the examination was carried out.At first of the examination, the concave mirror 1 to generate a virtualimage (which is simply displayed as a plane mirror in FIG. 5 and FIG. 6below), the video display apparatus 4, and the backlight 5 were preparedas a basic configuration, and one optical path folding mirror wasarranged between the video display apparatus 4 and the concave mirror 1.Simulation was carried out by using, as parameters, arrangement of therespective members and a distance from the video display apparatus 4 tothe concave mirror 1 so that volume of the information display apparatus100 becomes the minimum.

As a result, the volume when they were arranged so that video light fromthe video display apparatus 4 does not interfere with any of the membersbecame 3.6 liters. Then, examination about a direct method in which theoptical path folding mirror is removed was carried out for furtherminiaturization. FIG. 5 and FIG. 6 show results of the examination in alump. Further, actual numerical values in FIG. 6 are shown in Table 1.

TABLE 1 Distance between concave mirror and LCD (mm) 40 47.3 61.4 74.887 100 Volume of 1.31 1.33 1.40 1.50 1.60 1.74 optical path (l) Innervolume (l) 2.80 2.90 3.00 3.20 3.40 3.70

A configuration of the virtual image optical system according to thepresent invention will be described with reference to FIG. 5 . FIG. 5 isthe configuration diagram showing a basic configuration to conduct astudy for miniaturization in the virtual image optical system shown inFIG. 1 according to the first embodiment of the present invention. Inorder to simplify description thereof, an optical element for correctingaberration and distortion aberration is omitted, and across-sectionalshape in a vertical direction is shown as well as the windshield 6 shownin FIG. 4 . The liquid crystal panel is assumed as the video displayapparatus 4, and the video display apparatus 4 is arranged at a positionat which the virtual image of displayed video is obtained by the concavemirror 1 as a basic configuration in which the backlight 5 is arranged.

At this time, as shown in FIG. 5 , each of video light R2 generated fromvideo at a center, video light R1 generated from video at an upper end,and video light R3 generated at a lower end of the screen of the videodisplay apparatus 4 is arranged so that the light is not interfered andblocked out by the video display apparatus 4 when they are reflected bythe concave mirror 1, which becomes restriction in design.

In FIG. 6 , in view of the design restriction described above,horizontal: 7° and vertical: 2.6° of the FOV are set at the same time,and a virtual image distance is further set to 2 m. Volume of theinformation display apparatus 100 was determined by using an interval Zbetween the concave mirror 1 and the video display apparatus 4 (theliquid crystal panel and the backlight 5) as a parameter. In a casewhere a distance Z is 100 mm, they have a configuration shown in FIG.6(c). In this case, a vertical dimension of the concave mirror 1 can bemade the smallest. In a case where the distance Z is set to 75 mm, asshown in FIG. 6(b), an angle α₂ between a horizontal plane and theconcave mirror 1 becomes larger, and the vertical dimension of theconcave mirror 1 also becomes larger. When the distance Z is furtherreduced to be equal to or less than 50 mm, as shown in FIG. 6(a), anangle co between the horizontal plane and the concave mirror 1 furtherbecomes larger, and the vertical dimension of the concave mirror 1 alsofurther becomes larger.

FIG. 7 is a result obtained by simulating a relationship between a setheight and a set depth of the video display apparatus 4 by using thedistance Z as a parameter. As the distance Z is made smaller, the setdepth can be reduced, but the set height becomes higher. Similarly, FIG.8 is a view obtained by simulating a relationship between the distance Zand set volume L. Compared with volume of a space from the video displayapparatus 4 to the concave mirror (in FIG. 8 , optical path volume anddisplay), the set volume (containing volume of an LCD driving circuit, alight source driving circuit, and a backlight unit) changes as aboundary when the distance Z is 60 mm.

From the above, in order to miniaturize the information displayapparatus 100, it was found that it is necessary to realize the virtualimage optical system in which the distance Z to directly enlarge videodisplayed by the video display apparatus 4 with the concave mirror isshort, and that it is necessary for the center of a video display unitof the video display apparatus 4 in the vertical direction of the screento be arranged at a lower side than the center of the concave mirror 1.

On the other hand, in this arrangement, a distance (corresponding to theray R1) between the video display apparatus 4 and the upper end of theconcave mirror 1 becomes long, while a distance (corresponding to theray R3) between the video display apparatus 4 and the lower end of theconcave mirror 1 becomes short. Thus, by moving the video displayapparatus 4 in a direction shown by an arrow in FIG. 6(a) and moving thesame in a range so as not to interfere the video light (or block out thelight), they may be arranged so that the distance between the videodisplay apparatus 4 and the concave mirror 1 becomes even as much aspossible.

In the virtual image optical system according to the present invention,distortion correction of the virtual image between the video displayapparatus 4 and the concave mirror 1 and aberration correction by theoptical element that corrects aberration generated by the virtual imageare carried out. This will be described with reference to FIG. 9 .Namely, by arranging the video display apparatus 4 (object point) insidea focal point F (focal point distance f) with respect to a point O onthe optical axis of the concave mirror 1, it is possible to obtain thevirtual image by the concave mirror 1. In FIG. 9 , for convenience ofexplanation, the concave mirror 1 is regarded as a convex lens with thesame positive refractive power, and a relationship among the objectpoint, the convex lens (described by the concave mirror in FIG. 9 forconvenience of explanation), and the virtual image to be generated isshown.

In the present invention, the optical element 2 is arranged in order toreduce distortion and aberration that occur on the concave mirror 1.This optical element may be configured by a transmissive optical lens ora concave mirror. However, a direction of the light flux incident on theconcave mirror (an angle and a position thereof) is controlled so that:

-   -   (1) in a case where the video light from the video display        apparatus 4 is made incident on the reflecting surface as a        telecentric light flux, refractive power of the lens or the        concave mirror 1 substantially becomes zero;    -   (2) in a case where the video light from the video display        apparatus 4 is diverged and made incident on the optical        element, the optical element has positive refractive power; and    -   (3) in a case where the video light from the video display        apparatus 4 is focused and made incident on the optical element,        the optical element has negative refractive power.        Hereby, the distortion aberration of the generated virtual image        is corrected. Moreover, in case of the transmissive optical        lens, aberration regarding image forming performance generated        in the virtual image is corrected by interaction between an        incident surface at the video display apparatus 4 side and an        emission surface at the concave mirror 1 side.

At this time, as described above, in a size of the virtual image viewedand recognized by the driver, each of a distance a between the videodisplay apparatus 4 and the concave mirror 1 and a distance b betweenthe concave mirror 1 and the virtual image, which are generated due toinclination of the windshield, is different between the upper end andthe lower end of the virtual image.

For this reason, the inventors found that it is further better to reduceoccurring distortion aberration by inclining the video display apparatus4 with respect to the optical axis of the concave mirror 1 as shown inFIG. 9 to substantially match image magnification M′=b′/a′ of an upperend portion of the virtual image with image magnification M=b/a of alower end portion of the virtual image.

Moreover, by setting an average radius of curvature of a cross-sectionalshape of the optical element 2 in a vertical direction and an averageradius of curvature of a cross-sectional shape in a horizontal directionto different values, distortion aberration generated by an optical pathdifference that occurs due to a difference between the radius ofcurvature Rv in the vertical direction and the radius of curvature Rh inthe horizontal direction of the windshield described above andaberration to deteriorate the image forming performance of the virtualimage are corrected.

As mentioned above, in the information display apparatus 100 thatobtains a virtual image by directly reflecting video light to thewindshield 6, correction of aberration generated by the optical pathdifference that occurs due to the difference between the radius ofcurvature Rv in the vertical direction and the radius of curvature Rh inthe horizontal direction of the windshield 6 becomes the most importantfor securement of the image forming performance of the virtual image.

For this reason, the inventors reduced deterioration of the imageforming performance of the virtual image due to the difference betweenthe radii of curvature of the windshield described above by using afree-form surface shape (see Formula 1 below) capable of defining ashape of a surface as a function of an absolute coordinate (x, y) fromthe optical axis against an aspherical shape (see (Formula 2) below),which has been used in a conventional optical design, to define a shapeof a lens surface or mirror surface as a function of the distance r fromthe optical axis.

$\begin{matrix}{Z = {\frac{c \cdot \left( {x^{2} + y^{2}} \right)}{1 + \sqrt{1 - {\left( {1 + K} \right){c^{2} \cdot \left( {x^{2} + y^{2}} \right)}}}} + {\sum{\sum\left( {C{j\left( {m,n} \right)} \times x^{m} \times y^{n}} \right)}}}} & \left\lbrack {{Formula}1} \right\rbrack\end{matrix}$ j = [(m + n)² + m + 3n]/2 + 1

Note that the aspherical shape to define the shape of the lens surfaceor mirror surface is expressed as a function of the distance r from theoptical axis like Formula 2 below.

$\begin{matrix}{Z = {\frac{c \cdot h^{2}}{1 + \sqrt{1 - {\left( {1 + K} \right){c^{2} \cdot h^{2}}}}} + {A \times h^{4}} + {B \times h^{6}} + {C \times h^{8}} + {D \times h^{10}} + {E \times h^{12}} + {F \times h^{14}} + {G \times h^{16}} + {H \times h^{18}} + {J \times h^{20}}}} & \left\lbrack {{Formula}2} \right\rbrack\end{matrix}$

FIG. 10 is an enlarged view of a main portion of the liquid crystalpanel and a backlight light source 5 as the video display apparatus 4 inthe virtual image optical system according to the first embodimentdescribed above. By modulating light from the backlight by a videosignal inputted from a flexible board 10 of the liquid crystal panel,video is displayed on a liquid crystal panel display surface 11, and avirtual image is generated from the displayed video by the virtual imageoptical system (including a free-form surface concave mirror and afree-form surface optical element in the embodiment) to inform thedriver of video information.

In the configuration described above, an LED light source withrelatively inexpensive and high reliability as a solid light source isused for a light source element of the backlight light source 5. Asurface emission type of LED is used for high output. Therefore, lightutilization efficiency is improved by using technical ingenuity (will bedescribed later). Emission efficiency of the LED with respect to inputelectric power is different depending upon emission color, and is about20% to 30%. The remaining is almost converted into heat. For thisreason, as a frame to attach the LED, by providing a fin 13 for heatradiation configured by a member with high thermal conductivity (forexample, a metallic member such as aluminum) to radiate heat to theoutside, an effect to improve the emission efficiency of the LED itselfcan be obtained.

In particular, emission efficiency of an LED using red as emissioncolor, which currently goes on the market, is significantly deterioratedwhen junction temperature becomes higher, and chromaticity of videochanges at the same time. Thus, it is preferable that the light sourceelement is configured so that priority to reduce temperature of the LEDis raised and an area of the corresponding radiation fin becomes largerto improve cooling efficiency. In order to guide light diffused from theLED to the liquid crystal panel 4 efficiently, a light guide element 18is used in the example shown in FIG. 11 . However, it is preferable thatthe whole is covered by an exterior member 16 to unify the backlightlight source so that dust or the like does not adhere thereto, forexample.

Further, FIG. 11 shows an enlarged view of a main part of a light sourceunit including an LED that is a light source, a light guide element anda diffused plate. As is apparent from FIG. 11 , by inserting a mediumbetween the LEDs to optically connect openings 21 a, 22 a, 23 a, 24 athat take in divergent light rays from LEDs of light funnels 21, 22, 23,and 24 to each other as a plane or by having a focusing action as aconvex shape to cause the light source light to be diverged to becomeparallel light as much as possible, an incident angle of light madeincident on a boundary surface of the light funnel is made smaller. As aresult, the divergent angle can further be made smaller after passingthrough the light funnel. Therefore, control of the light source lightdirected to the liquid crystal panel after being reflected by the lightguide element 18 can be facilitated.

Moreover, in order to improve utilization efficiency of divergent lightfrom the LED, polarization conversion is carried out for a joiningportion 25 between the light funnels 21 to 24 and the light guideelement 18 by using a PBS (Polarizing Beam Splitter) to convert that ofthe light to a desired polarization direction, whereby it is possible toimprove efficiency of incident light to the LCD.

In a case where the polarization direction of light source light isuniformed as described above and material with low birefringence is usedas raw material of the light guide element 18 to rotate a direction ofthe polarized wave and pass through the liquid crystal panel, it isfurther preferable that problems such as coloring at the time of blackdisplay does not occur, for example.

As mentioned above, the light flux from the LED whose divergent angle isreduced is controlled by the light guide element; is reflected by atotally reflecting surface that is provided an inclined surface of thelight guide element 18; is diffused by a diffusing member 14 arrangedbetween an opposing surface and the liquid crystal panel; and is thenmade incident on the liquid crystal panel 4 as the video displayapparatus. In the present embodiment, as described above, the diffusingmember 14 is arranged between the light guide element 18 and the liquidcrystal panel 4. However, the similar effect can be obtained even thougha diffusing effect is caused to have an end surface of the light guideelement 18 to provide a fine uneven shape, for example.

Next, a configuration of the light guide element 18 described above andeffects obtained by the same will be described with reference to FIG. 12and FIG. 13 . FIG. 12 is an outline view showing the light guide element18 according to the present invention. The light flux whose divergentangle is reduced by the light funnels 21 to 24 shown in FIG. 11 is madeincident on a light incident surface 18 a of the light guide element 18.At this time, the divergent angle of the vertical direction (verticaldirection in FIG. 13 ) is controlled by a shape (FIG. 13 shows across-sectional shape) effect of the incident surface, and the lightflux efficiently transmits within the light guide element 18.

FIG. 13 is an enlarged cross-sectional view of a main portion of thelight guide element. The light source light whose divergent angle isreduced by the light funnels 21 to 24 is made incident from the incidentsurface 18 a via the joining portion 25 as described above, and istotally reflected by a prism 18 as the light guide element 18, which isprovided on the opposing surface, toward an opposing surface 17. A shapeof the totally reflecting prism 18 is divided and formed in a stepwiseshape in the vicinity (enlarged view of B portion) of and at an endportion (enlarged view of A portion) of the incident surface 18 a inaccordance with the divergent angle of the light flux made incident oneach surface, whereby an angle of the totally reflecting surface iscontrolled. On the other hand, an arrival position and an amount ofenergy of the divided light flux after reflection are controlled byusing a division dimension of the totally reflecting surface describedabove as variables so that light quantity distribution of the light fluxmade incident on the liquid crystal panel 4 that is the video displayapparatus becomes uniform in the emission surface of the liquid crystalpanel 4.

FIG. 14 shows a result obtained by simulating a state where emissionlight from the backlight described above passes through the liquidcrystal panel in the information display apparatus according to thepresent invention 100. FIG. 14(a) is a view showing an emission state oflight when viewed from a longitudinal direction of the liquid crystalpanel. FIG. 14(b) shows an emission state of light when viewed from ashort direction (that is, a direction perpendicular to the longitudinaldirection thereof) of the liquid crystal panel. In the presentinvention, the horizontal angle of the FOV is widened more than itsdesign. Therefore, it is designed that brightness of the virtual imageviewed and recognized by right and left eyes is not changed extremelyeven in a case where a diffusion angle in a horizontal direction isenlarged with respect to that in a vertical direction and a position ofeyes is moved by rotation of the driver's head.

Further, like the embodiment of the present invention, FIG. 15 and FIG.16 show brightness distribution of the emission surface of the liquidcrystal panel 4 and a method of characteristic evaluation of the liquidcrystal panel in case of using the backlight by controlling an emissiondirection and intensity of light by using the light guide element 18. Asis apparent from FIGS. 15 and 16 , inclination of deterioration ofbrightness outside an effective range of the vertical direction (longside direction) of the screen can be made smaller with respect to thebrightness distribution of the vertical direction (short side direction)of the screen.

The emission light (video light) from the liquid crystal panel that isused as the video display apparatus in the information display apparatusaccording to the present invention 100 indicates predeterminedtransmittance in a range of ±50° as shown in FIG. 17 and FIG. 20 in acase where visual angles in horizontal and vertical directions are usedas a parameter. In a case where a range of the visual angle falls within±40°, it is possible to obtain a better transmittance characteristic. Asa result, as shown in FIG. 18 and FIG. 21 , brightness of the screengreatly varies depending upon a direction to view the screen (visualangle) in the horizontal direction and the vertical direction of adisplay screen. This is caused by an angular characteristic of backlightbrightness shown in FIG. 19 and FIG. 22 .

For this reason, the inventors obtained high brightness by controllingthe angle of the totally reflecting surface of the light guide element18 and the divergent angle of the light source light from the LEDs ofthe light funnels 21 to 24 to narrow visual angle property of thebacklight into a small range so that the emission light from the liquidcrystal panel 4, which is taken in the virtual image optical system, canbe obtained as light vertical to the screen as much as possible.Specifically, as shown in FIG. 18 and FIG. 21 , in order to obtain videowith high brightness, light in a range of ±30° in a right-and-leftviewing angle is used, and contrast performance shown in FIG. 23 andFIG. 25 is considered. By narrowing it to ±20° or smaller, the virtualimage using a source image with good image quality could be obtained atthe same time.

As mentioned above, the contrast performance that influences the imagequality of the video display apparatus is determined by to what extentbrightness when black as a basis to determine image quality is displayed(in FIG. 24 and FIG. 26 , indicated by “black display brightness”) canbe lowered. For this reason, it is preferable that an iodine-basedpolarizing plate in which the degree of polarization is high is usedbetween the liquid crystal panel 4 and the backlight.

On the other hand, by using a dye-based polarizing plate as a polarizingplate provided at the optical element 2 side (light emission surface),it is possible to obtain high reliability even in a case where outsidelight enters therein or ambient temperature is high.

In a case where color display is executed in the liquid crystal panel 4,color filters corresponding to the respective pixels are provided. Forthis reason, in a case where light source color of the backlight iswhite, light absorption with the color filters becomes greater, and lossthereof becomes larger. Thus, as shown in FIG. 11 described above, theinventors use a plurality of LEDs:

-   -   (1) to add a green LED whose contribution to brightness is large        compared with the case where a plurality of white LEDs is used.    -   (2) to add a red or blue LED to the white LED to improve glossy        property of an image.    -   (3) to individually arrange red, blue, and green LEDs, add a        green LED whose contribution to brightness is large, and        individually drive the LEDs, thereby enlarging a color        reproduction range to heighten glossy property as well as to        improve brightness.    -   (4) to raise transmittance of each color filter with respect to        peak brightness of red, blue, green LEDs by implementing the        above (3) to improve brightness as a whole.    -   (5) to reduce damage of the polarizing plate at an incident side        of the liquid crystal panel as a second embodiment of the        backlight by arranging the PBS between the light funnels and the        light guide element to uniform it to a specific polarized wave.        It goes without saying that a polarization direction of the        polarizing plate that is arranged at the incident side of the        liquid crystal panel may be a direction through which the        polarized wave uniformed to a specific direction after passing        through the PBS (Polarizing Beam Splitter) passes.

As mentioned above, as a video light source apparatus 4 according to theembodiment of the present invention, a λ/4 plate can be provided on theemission surface of the liquid-crystal display panel to convert theemission light to circular polarized light. As a result, the driver isallowed to monitor a good virtual image even though he or she wearspolarized sunglasses.

Moreover, by forming reflection coating for the reflecting mirror usedin the virtual image optical system by metallic multilayer, angulardependence of reflection power is small, and the reflection power isnever changed by a polarization direction (a P wave or S wave).Therefore, it becomes possible to uniformly keep chromaticity andbrightness of the screen.

Moreover, in a case where an ultraviolet ray reflecting film or anoptical member obtained by combining the ultraviolet ray reflecting filmand an infrared ray reflecting film is provided between the virtualimage optical system and the windshield, temperature rise of theliquid-crystal display panel and the polarizing plate and damagetherefrom can be reduced even though outside light (solar light) entersit. Therefore, an effect that reliability of the information displayapparatus is not impaired can be obtained.

Further, in the virtual image optical system, optimum design including adifference between the radius of curvature in the horizontal directionand the radius of curvature in the vertical direction of the windshieldthat is the projected member in the conventional technique in thevehicle is carried out. The concave mirror 1 whose concave surface facesthe windshield 6 side is arranged between the windshield and the videodisplay apparatus or an intermediate image display unit. This causesvideo of the video display apparatus to be enlarged, and the video isreflected by the windshield 6. At this time, the optical element isarranged between the concave mirror 1 described above and the videodisplay apparatus 4. On the other hand, video light flux to form anenlarged image (virtual image) of the video, which is formed so as tocorrespond to a viewpoint position of the driver, passes through theoptical element arranged between the concave mirror and the videodisplay apparatus, thereby correcting distortion and/or aberration thatoccurs in the concave mirror 1. For that reason, a virtual image inwhich distortion and aberration are reduced significantly can beobtained compared with the virtual image optical system including onlythe conventional concave mirror.

Moreover, in the present invention shown in FIG. 1 , it is necessary toform a virtual image obtained by being reflected at the upper portion ofthe windshield 6 (that is, an upper portion in a vertical direction ofthe vehicle body) at a far position. For this reason, in order tofavorably form the video light flux diverged from the upper portion ofthe video display apparatus by which the video corresponding to this isdisplayed, it is necessary that a focal point distance f1 of the opticalelement arranged between the concave mirror 1 described above and thevideo display apparatus 4 is made shorter, and to the contrary, thevirtual image obtained by being reflected at the lower portion of thewindshield 6 (that is, a lower portion in a vertical direction of thevehicle body) is formed in the vicinity thereof. For this reason, inorder to favorably form the video light flux diverged from the lowerportion of the video display apparatus by which the video correspondingto this is displayed, a composite focal point distance f2 of a pluralityof optical elements arranged between the concave mirror 1 describedabove and the video display apparatus 4 may be set to be relativelylonger.

Further, in the present invention, the radius of curvature in thehorizontal direction (parallel to the ground) of the windshield 6 isdifferent from the radius of curvature in the vertical direction (thatis, a direction vertical to the horizontal direction of the windshield),whereby screen distortion of the virtual image viewed by the driver iscorrected. Therefore, by arranging the optical element whose axissymmetric property is different with respect to the optical axis in thevirtual image optical system, correction of the distortion describedabove is achieved.

As described above, the sheet-like light source apparatus suitable to beused for an electronic apparatus provided with the image display deviceaccording to various embodiments of the present invention has beendescribed. However, the present invention is not limited to theembodiments described above, and various modifications are contained.For example, the whole system has been explained in detail in theembodiments described above for explaining the present inventionclearly. The present invention is not necessarily limited to one thatincludes all configurations that have been explained. Further, a part ofthe configuration of one embodiment can be replaced by a configurationof the other embodiment. Further, a configuration of the otherembodiment can be added to a configuration of one embodiment. Moreover,a part of the configuration of each of the embodiments can be added tothe other configuration, deleted or replaced thereby.

REFERENCE SINGS LIST

100 . . . information display apparatus, 101 . . . vehicle, 1 . . .concave mirror, 2 . . . optical element, 4 . . . liquid-crystal displaypanel, 5 . . . backlight light source, 6 . . . projected member(windshield), 7 . . . housing, V1 . . . virtual image, 8 . . . EyeBox(eyes of observer), 9 . . . light source unit, R1 . . . upper videolight, R2 . . . central video light, R3 . . . lower video light, 10 . .. flexible board, 11 . . . video display surface, 12 . . . frame, 13 . .. fin, 14 . . . diffusing member, 16 . . . exterior member, 17 . . .emission surface, 18 . . . light guide element, 20 . . . light funnelunit, 21 . . . light funnel, 22 . . . light funnel, 23 . . . lightfunnel, 24 . . . light funnel, 21 a . . . light funnel opening, 22 a . .. light funnel opening, 23 a . . . light funnel opening, 24 a . . .light funnel opening, 25 . . . joining portion (PBS).

1. A head-up display apparatus comprising: a display panel configured todisplay an image; and a reflecting mirror configured to reflect lightfrom the display panel, wherein an optical distance between thereflecting mirror and the display panel is changed to continuouslychange a display position of a virtual image from a distant place to anadjacent position, such that a virtual image obtained by being reflectedat an upper portion of a windshield is formed farther than a virtualimage obtained by being reflected at a lower portion of the windshieldwhen viewed from a viewpoint position of a driver.
 2. The head-updisplay apparatus according to claim 1, wherein transmittance ofemission light from the display panel indicates a predeterminedtransmittance in a range of ±50° of a visual angle in a horizontaldirection of the display panel.
 3. The head-up display apparatusaccording to claim 1, wherein an iodine-based polarizing plate isprovided at a light incident surface of the display panel, and adye-based polarizing plate is provided at a light emission surface ofthe display panel.
 4. The head-up display apparatus according to claim1, wherein a distance between the display panel and an upper end of thereflecting mirror is longer than a distance between the display paneland a lower end of the reflecting mirror.
 5. The head-up displayapparatus according to claim 1, wherein a distance between the displaypanel and the reflecting mirror, and a distance between the reflectingmirror and the virtual image differs at an upper portion and a lowerportion of the virtual image.
 6. The head-up display apparatus accordingto claim 1, wherein the reflecting mirror is arranged such thatreflected light from the reflecting mirror is not blocked by the displaypanel.
 7. The head-up display apparatus according to claim 1, whereinthe display panel is arranged so that a center of a display region ofthe display panel is located at a side lower than a center of thereflecting mirror with respect to a vertical direction.
 8. The head-updisplay apparatus according to claim 1, wherein the reflecting mirror isarranged on an optical path between the display panel and a projectionsurface of the windshield.
 9. The head-up display apparatus according toclaim 1, wherein the display panel is arranged so as to be inclined withrespect to an optical axis of the reflecting mirror.